Hadronic b’ search at the LHC with top and W taggers
Shuo Yang (杨硕 )/ Dalian University in collaboration with Ji Jiang,Qi-Shu Yan,Xiaoran Zhao
arXiv1405.2514
2014.5.17 Conference of TeV Physics Working Group @Sun Yat-Sen University
• Vector-like b’ quark
• Jet Substructure and top-tagger W-tagger
• Hadronic b’ search with top and W taggers
• Summary
Outline
I. Vector-like b’
• The chiral fourth generation has been almost ruled out by the Higgs data.
• Vector-like quarks
left-handed and right-handed components transform the same
under SU(2)L*U(1)Y
the charged current of vector-like fermions are Vector Structure
Vector-like quarks
Features of vector-like quark
• Gauge invariant mass term without the Higgs
• Doesn’t introduce anomaly
• Work well with EWPT
• Dangerous FCNCS Bounds on mixing parameters
Vector-like quarks in New Phyiscs models
• Warped or universal Extra dimensions KK excitations of bulk fields
• Little Higgs models Partners of SM fermions for cancel the quadratic divergence of Higgs
• Non-minimal SUSY extensions VLQs increase corrections to Higgs mass without affecting EWPT
• Composite Higgs models VLQs appear as the excited resonances of the bounded states which
from SM particles
… …
Search for vector-like b’• b’tW b’ bh b’bZ b’Wq
Golden channel : same sign lepton final state
The most stringent limit comes from CMS.
mb’ > 582 GeV ( Br(b’bZ)=100%)
mb’ > 732 GeV
Br(b’tW)=100% based on same sign lepton final states
Motivations for the search of fully hadronic mode
• This mode has large branching ratio.• Difficult to analyze missing energy in multilepton channel• It is independent to confirm the theoretical prediction. • Current detectors has the capacity to detect some signal in all-hadronic final states. D0 collaboration hep-ex/0612040 CDF collaboration 0703.3790 CMS collaboration 1307.4617 ATLAS collaboration 1108.4755 CMS collaboration 1204.2488
• The development of jet substructure technique can help.• There are recent studies on the phenomenology in fully hadronic mode. SY and Qi-Shu Yan 1111.4530 M.R.Buckly, T. Plehn et al 1310.6034 M. Endo et al 1405.2677
What is jet?quark quark
quark quark
gluon
had
ron
isa
tion
Why do we see jets? Parton fragmentation
II. Jet Substructure and T-tagger and W-tagger
Jet Algorithms
Cone Algorithm Recombination AlgorithmUAI,JetCLU,SISCone…. Jade,Kt, Cambrige-Aachen, Anti-Kt….
Based on fixed geometryIdea: Put cone along dominatant direction of flow direction
Idea: Undo branching
Jet Substructure
Rest frame
Lab frame
R=0.4 R=0.7
Hadronically decaying EW massive particles at high Pt = 2 jets
Boosted Massive Particles
Jet cone size and fat jet
R=0.5
R=1.5
R=1.0
In order to separate signal, one have to anatomize the Jet Substructure!
Brief history of Jet Substructure• Michael H. Seymour Searches for new particles using cone and cluster jet
algorithms: A Comparative study, Jun 1993, Z. Phys. C62(1994) 127-138
• Butterworth, Cox, Forshaw, Jan 2002 WW scattering at the CERN LHC, Phys. Rev. D65 (2002) 096014
• Butterworth, Davison, Rubin, Salam, Feb 2008, Jet substructure as new Higgs search channel at the LHC, Phys.Rev.Lett.100(2008) 242001.
• Kaplan, Rehermann, Schwartz and Tweedie, ``Top Tagging: A Method for Identifying Boosted Hadronically Decaying Top Quarks,'' Phys. Rev. Lett.101(2008) 142001
• Grooming :Filtering ,Trimming, Pruning ,
• Variable R, Nsubjettiness, Dipoloarity…….
• Higgs –tagger, top-tagger, W-tagger …..
• ………………
JH Top Tagger John Hopkins Group PRL101 (2008)142001
Exp for Jet Substructure
III. Hadronic b’ search with top-tagger and W-tagger
SY, Ji Jiang, Qi-Shu Yan, Xiaoran Zhao arXiv1405.2514
taggered top
taggered W
Features of the signal
Tagged top and W (HEPTopTagger and CMS Wtagger algorithms are used)
Part 3
14
22
Finding the missing objects:Part 3
9
9
LHC sensitivity
IV Summary
• Jet Substructure is helpful to identify highly boosted massive particles or to tell the jet origin.
• By studying the processes pp b’b’twtw in fully hadronic mode, we find that the combinatorics can
be reduced and backgrounds can be suppressed
significantly with top taggers and W taggers.
Backup
Illustration for collinear safety (left) and collinear unsafety in an IC-PR algorithm(right)
Refine the jet resolution
• Filtering: break jet into subjets on angular scale Rfilt , take n filtered hardest subjets.
• Trimming: break jet into subjets on angular scale Rtrim, take all subjets with Pt,sub>εPt,jet
• Pruning: If the subjets about to be recombined have ΔR>Rprune and min(Pt1,Pt2)< ε(Pt1+Pt2), discard the softer one.
1. Calculate the distance dij between all pairs of pseudo-jets and the beam distance diB for each pseudo-jet.
2. Find the minimum in the list of dij and diB .
3. If the minimum is dij, recombine i and j into a new particle and then return to step 1.
4. If it is diB, define it as a final-state jet and remove it from the jet list. Return to step 1.
5. Iterate this process until the original list is empty, i.e., all peudo-jets have been clustered to jets.
The dij and diB in most popular sequential recombine algorithms for use at the LHC can be parameterized as:
P is a parameter, 1 for kt, -1 for anti-kt, 0 for CA
Borrowed from Salam’s talk